By using the series approach make a derivation for the total amplitude reflection coefficient from a...

[Optics problem-please probide detailed solution, thanks!] Using the series approach to derive the total amplitude reflection...

[Optics problem-please probide detailed solution, thanks!] Using the series approach to derive the total amplitude reflection coefficient from a dielectric plate of thickness d and refractive index n. The incidence angle is ?i.

calculate the amplitude and phase of the reflection coefficient for a plane wave incident on a...

calculate the amplitude and phase of the reflection coefficient for a plane wave incident on a sediment with density 1200kg/m^3, sound speed 1700 m/s at an angle of incidence of 70degrees. answers 1 and 30degress. I know I can get z1=(rho1 x speed of sound1)/cos(theta incidence) but no idea what I can get out of that and according to my book notes when the speed of sound in the second fluid is faster than the first fluid the magnitude of...

The Fresnel reflection can loss about 4% from air to glass so we can make the...

The Fresnel reflection can loss about 4% from air to glass so we can make the reflection loss at minimum by coat a layer of a material that has refractive index n3 = squre root(n1*n2) with a thickness to have destructive interference. If our central wavelength is 800 nm, find the following: 1) The minimum thickness of this coating. 2) The minimum reflection coefficient at central wavelength. 3) The bandwidth of the AR coating? the bandwidth can be with the...

Cellulose has a refractive index of 1.4613. What is the angle of total internal reflection when...

Cellulose has a refractive index of 1.4613. What is the angle of total internal reflection when a ray of light travels from cellulose into air? Assume refractive index of air is 1. Two decimal places, in degrees

8 a) Which direction does an EM wave travelling from a denser medium (higher refractive index)...

8 a) Which direction does an EM wave travelling from a denser medium (higher refractive index) to a rarer medium (lower refractive index) refract to with respect to the normal to the media boundary? 8 b) What are the possible values of the phase angle of the reflection coefficient (θr) when the and electromagnetic wave travels from one lossless dielectric medium to another lossless dielectric medium at normal angle of incidence? 8 c) A plane wave travels from medium 1...

a beam of light travels from air into a sheet of glass having refractive index n....

a beam of light travels from air into a sheet of glass having refractive index n. a if we increase n, the angle of incidence, decreases b if we double the angle of incidence, the angle of reflection also doubles c the angle of refraction will be greater than the angle of incidence \ d if the angle of incidence is large enough, the light will be totally reflected back into the air e if we increase the angle of...

True or False? A)Reflection is the description of the portion of a ray of light that...

True or False? A)Reflection is the description of the portion of a ray of light that remains in the medium from which it originated after striking the boundary of a different medium. B)Refraction refers to the change in direction of the ray of light entering a new medium. C)The angle of incidence equals the angle of refraction. D)Angles in optics are measured with respect to the surface. E)The intensity of the reflected beam is greater than the intensity of the...

When passing from a slower region into a faster region, it is possible for a wave...

When passing from a slower region into a faster region, it is possible for a wave to experience Total Internal Reflection (TIR): for certain angles, the entire wave will be reflected, with no transmitted portion. Using Snell’s law, solve for the critical angle of incidence θi, at which TIR begins to occur by setting the transmitted angle equal to 90 degree . Then, use this value to find the reflection coefficient R at the critical angle.

Problem Two: a. Derive or explain the condition for total internal reflection b. A beam of...

Problem Two: a. Derive or explain the condition for total internal reflection b. A beam of monochromatic light is put into a fiber optic cable. The fiber has index of refraction of 1.55 . It is surrounded by a “cladding” with index of refraction 1.36 and then an absorbing protective black layer. At what minimum angle of incidence is the light reflected back into the fiber ? c. We now have two ways to transmit digital information a distance of...

10. A spherical conductor of radius R = 1.5cm carries the charge of 45μ, (a) What...

10. A spherical conductor of radius R = 1.5cm carries the charge of 45μ, (a) What is the charge density (ρ) of the sphere? (b) Calculate the electric field at a point r = 0.5cm from the center of the sphere. (c) What is the electric field on the surface of the sphere? 11. Two capacitors C1 and C2 are in series with a voltage V across the series combination. Show that the voltages V1 and V2 across C1 and...